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PAPR Investigation on FDMA Transmission Follow-up

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Presentation on theme: "PAPR Investigation on FDMA Transmission Follow-up"— Presentation transcript:

1 PAPR Investigation on FDMA Transmission Follow-up
Month Year doc.: IEEE yy/xxxxr0 September 2018 PAPR Investigation on FDMA Transmission Follow-up Date: Authors: Name Affiliation Address Phone Eunsung Park LG Electronics 19, Yangjae-daero 11gil, Seocho-gu, Seoul , Korea Dongguk Lim Jinsoo Choi Eunsung Park, LG Electronics John Doe, Some Company

2 September 2018 Introduction In [1], we studied phase rotation and PAPR for both legacy and WUR portions in the FDMA transmission In this contribution, we propose phase rotation values which are applied to 20MHz sub-channels for the WUR portion in 40MHz and 80MHz FDMA transmissions To this end, we further investigate the PAPR by considering three example sequences for the construction of 2us and 4us MC-OOK On symbols Eunsung Park, LG Electronics

3 Assumption (1/2) September 2018
For 40MHz, we investigate PAPR for the full allocation case only, i.e., all sub-channels are allocated to the WUR PPDU transmission For 80MHz, we consider the preamble puncturing mode There are various partial allocation cases as well as the full allocation case (2^4 cases) To obtain optimal phase rotation values, the minimax approach is applied, i.e., we first calculate the PAPR for all of the allocation cases by applying a certain phase rotation, choose the maximum PAPR among all allocation cases in that phase rotation, then repeat this procedure in other candidates of the phase rotation and finally compare those maximum PAPRs E.g., K allocation cases and L phase rotation candidates PAPR for allocation case 1 PAPR for allocation case 2 PAPR for allocation case K Phase rotation 1 Choose max PAPR Phase rotation L Phase rotation 2 Compare these PAPR and pick up the best phase rotation which minimizes the max PAPR Eunsung Park, LG Electronics

4 September 2018 Assumption (2/2) To calculate the PAPR in each allocation case, we consider all ‘ON’ and ‘OFF’ combinations of sub-channels allotted to the WUR FDMA transmission The WUR PPDU structure used for the PAPR calculation is shown in Appendix A The same OOK symbol length is used, i.e., all sub-channels are composed of either 2us or 4us OOK symbol When all sub-channels use the same data rate, we can consider all sub-channels are composed of either 2us or 4us OOK symbol for HDR or LDR, respectively When different data rates are used in sub-channels, we can consider all sub-channels consist of 2us OOK symbol, i.e., 4us OOK symbol for LDR is constructed by two consecutive 2us OOK symbols used for HDR Eunsung Park, LG Electronics

5 Phase Rotation and PAPR for 40MHz (1/3)
September 2018 Phase Rotation and PAPR for 40MHz (1/3) 4us On symbol Sequence Option 1 : [ ] Sequence Option 2 : [-9-5i -7+9i -1+1i 9+15i 15-9i -9+1i 0 1-9i 9-15i 15+9i -1+1i 9-7i 5+9i]/sqrt(170) Sequence Option 3 : [ ](1+1i) Red: optimal phase rotation Phase rotation {1 1} {1 -1} {1 j} {1 –j} PAPR 8.0812 8.0231 8.0734 8.0761 Phase rotation {1 1} {1 -1} {1 j} {1 –j} PAPR 7.0920 7.1939 7.1505 7.1724 Phase rotation {1 1} {1 -1} {1 j} {1 –j} PAPR 8.2583 8.1696 8.2590 8.2563 Note : We assume 1, -1, j and –j as the coefficient of phase rotation and thus, in 40MHz, when the first coefficient is set to 1, there are only 4 candidates for phase rotation Eunsung Park, LG Electronics

6 Phase Rotation and PAPR for 40MHz (2/3)
September 2018 Phase Rotation and PAPR for 40MHz (2/3) 2us On symbol Sequence Option 1 : [ ] Sequence Option 2 : [3+7i i i i i 0 7+3i]/sqrt(170) Sequence Option 3 : [ ] Red: optimal phase rotation Phase rotation {1 1} {1 -1} {1 j} {1 –j} PAPR 8.2509 8.1682 8.2585 8.2581 Phase rotation {1 1} {1 -1} {1 j} {1 –j} PAPR 6.5955 6.6416 6.6366 6.6044 Phase rotation {1 1} {1 -1} {1 j} {1 –j} PAPR 9.3301 9.3934 9.4167 9.4171 Eunsung Park, LG Electronics

7 Phase Rotation and PAPR for 40MHz (3/3)
September 2018 Phase Rotation and PAPR for 40MHz (3/3) In each sequence option, the difference in PAPR among all phase rotation candidates is quite small, even though either the phase rotation of {1 -1} or {1 1} is optimal in terms of PAPR All of the PAPRs are also lower than the worst PAPR of the L-SIG shown in Appendix B L-SIG may have the highest PAPR in the WUR PPDU Thus, in consideration of a simple implementation, the unified phase rotation between legacy and WUR parts is more preferable The phase rotation {1 j} used for 11ac in 40MHz can be applied to the legacy preamble and we also propose to use this value for the WUR part Eunsung Park, LG Electronics

8 Phase Rotation and PAPR for 80MHz (1/3)
September 2018 Phase Rotation and PAPR for 80MHz (1/3) 4us On symbol Sequence Option 1 : [ ] Sequence Option 2 : [-9-5i -7+9i -1+1i 9+15i 15-9i -9+1i 0 1-9i 9-15i 15+9i -1+1i 9-7i 5+9i]/sqrt(170) Sequence Option 3 : [ ](1+1i) Red: optimal phase rotation Green: second best thing among four cases Phase rotation { } { } { } { } Max PAPR 8.7850 8.7990 9.8415 Phase rotation { } { } { } { } Max PAPR 7.9045 7.8790 8.9549 Phase rotation { } { } { } { } Max PAPR 8.9642 8.9865 Note : In 80MHz, there are 4^3 candidates for phase rotation when the first coefficient is set to 1, but we just show the results of four candidates including optimal and conventional ones as well as no phase rotation case Eunsung Park, LG Electronics

9 Phase Rotation and PAPR for 80MHz (2/3)
September 2018 Phase Rotation and PAPR for 80MHz (2/3) 2us On symbol Sequence Option 1 : [ ] Sequence Option 2 : [3+7i i i i i 0 7+3i]/sqrt(170) Sequence Option 3 : [ ] Red: optimal phase rotation Green: second best thing among four cases Phase rotation { } { } { } { } Max PAPR 8.9644 8.9851 Phase rotation { } { } { } { } Max PAPR 9.6052 7.3620 7.3496 8.4021 Phase rotation { } { } { } { } Max PAPR Eunsung Park, LG Electronics

10 Phase Rotation and PAPR for 80MHz (3/3)
September 2018 Phase Rotation and PAPR for 80MHz (3/3) In each sequence option, either the phase rotation of { } or { } is optimal in terms of PAPR and these values even have a similar PAPR The conventional phase rotation { } also still has better PAPR than the worst PAPR of the L-SIG given in Appendix B but leads to much higher PAPR than those of the phase rotation values above Its PAPR is over 1dB worse than the optimal one in all options For a simple implementation and unified solution, the conventional phase rotation { } can be applied, but in consideration of hardware efficiency, the phase rotation of { } or { } is more preferable Eunsung Park, LG Electronics

11 September 2018 Conclusion We have investigated the PAPR and proposed phase rotation values for the WUR part in WUR FDMA For 40MHz, we have proposed to use the conventional phase rotation {1 j} For 80MHz, we have proposed to use { } or { } Eunsung Park, LG Electronics

12 September 2018 Straw Poll #1 Do you agree to use the phase rotation of [1 j] for the WUR portion encompassing WUR-Sync and WUR-Data fields in the 40MHz FDMA transmission? Y/N/A : // Eunsung Park, LG Electronics

13 September 2018 Straw Poll #2 Do you agree to use the phase rotation of [ ] or [ ] for the WUR portion encompassing WUR-Sync and WUR-Data fields in the 80MHz FDMA transmission? Y/N/A : // Eunsung Park, LG Electronics

14 September 2018 References [1] IEEE /0802r1 PAPR Investigation on FDMA Transmission Eunsung Park, LG Electronics

15 Appendix A – PAPR for WUR Portion
September 2018 Appendix A – PAPR for WUR Portion In 40MHz, to calculate the PAPR, we consider that the PPDU is composed of 4 ‘ON’ and ‘OFF’ combinations as follows If each ‘ON’ and ‘OFF’ combination occurs almost evenly in a practical WUR PPDU, this PPDU format may be reasonable for the PAPR calculation PAPR is calculated by applying each candidate of phase rotation In 80MHz with the full allocation case, we consider that the PPDU is composed of 16 ‘ON’ and ‘OFF’ combinations Sub-channel 1 Sub-channel 2 2us us us us for 7 length sequence 4us us us us for 13 length sequence OFF ON ON OFF ON OFF ON OFF PAPR is measured by applying each candidate of phase rotation Eunsung Park, LG Electronics

16 Appendix A – PAPR for WUR Portion
September 2018 Appendix A – PAPR for WUR Portion In 80MHz with the partial allocation case, we consider that the PPDU is composed of 2^n ‘ON’ and ‘OFF’ combinations n is the number of allocated sub-channels for the FDMA transmission E.g., Partial allocation with sub-channel 3 punctured in 80MHz Eunsung Park, LG Electronics

17 Appendix B – PAPR for Legacy Preamble
September 2018 Appendix B – PAPR for Legacy Preamble Conventional phase rotation values are applied to the legacy preamble part PAPR for L-STF and L-LTF [dB] PAPR for 40MHz Max PAPR for 80MHz L-STF 5.2497 6.8606 L-LTF 5.7938 7.9370 Eunsung Park, LG Electronics

18 Appendix B – PAPR for Legacy Preamble
September 2018 Appendix B – PAPR for Legacy Preamble PAPR for L-SIG [dB] Following cases are considered for the PPDU length Definition of case L_length (octets) case0 FB=0, HDR 192 case6 FB=6, HDR 336 Case12 FB=12, HDR 480 case1 FB=0, LDR 672 case7 FB=6, LDR 1248 Case13 FB=12, LDR 1824 case2 FB=2, HDR 240 case8 FB=8, HDR 384 Case14 FB=14, HDR 528 case3 FB=2, LDR 864 case9 FB=8, LDR 1440 Case15 FB=14, LDR 2016 case4 FB=4, HDR 288 case10 FB=10, HDR 432 Case16 FB=16, HDR 576 case5 FB=4, LDR 1056 case11 FB=10, LDR 1632 case17 FB=16, LDR 2208 Eunsung Park, LG Electronics

19 Appendix B – PAPR for Legacy Preamble
September 2018 Appendix B – PAPR for Legacy Preamble PAPR for L-SIG [dB] Red: maximum PAPR among all L_Length cases PAPR for 40MHz Max* PAPR for 80MHz Case 0 8.1208 Case 9 8.2288 Case 1 9.7488 Case 10 8.6453 Case 2 8.3897 Case 11 9.0901 Case 3 7.6770 Case 12 8.6271 Case 4 9.5330 Case 13 8.3736 Case 5 8.1310 Case 14 8.6528 Case 6 8.2794 Case 15 9.5472 Case 7 8.2987 Case 16 9.1345 Case 8 9.9882 Case 17 8.5720 Max PAPR for 80MHz : In each L_Length case for 80MHz, the table shows only the maximum PAPR among those of all allocation cases including full and partial allocation cases Eunsung Park, LG Electronics

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